Medical

MIT supercharges cancer immunotherapy with a booster vaccine

MIT supercharges cancer immunotherapy with a booster vaccine
T cells (red) and B cells (blue) in the lymph nodes, after the vaccine CAR-T cell therapy kicks them into overdrive
T cells (red) and B cells (blue) in the lymph nodes, after the vaccine CAR-T cell therapy kicks them into overdrive
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An MIT team has developed a vaccine to stimulate T cells (red) to attack solid tumors in mice
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An MIT team has developed a vaccine to stimulate T cells (red) to attack solid tumors in mice
T cells (red) and B cells (blue) in the lymph nodes, after the vaccine CAR-T cell therapy kicks them into overdrive
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T cells (red) and B cells (blue) in the lymph nodes, after the vaccine CAR-T cell therapy kicks them into overdrive

Our bodies have powerful built-in defenses in the form of the immune system, but sometimes it needs an extra push. Chimeric Antigen Receptor (CAR) T cell therapy involves reprogramming T-cells to hunt down cancer, which has been effective against blood cancers but not so much against solid tumors. Now, scientists at MIT have found a way to supercharge the technique with a vaccine booster.

CAR-T cell therapy involves removing T cells from a patient, programming them to target proteins found on the surface of cancer cells, then reintroducing them to the body. The technique has proven successful against some forms of leukemia but hasn't translated well to other types of cancer, particularly solid tumors.

So MIT researchers set out to find a way to boost the effectiveness of CAR-T therapy. Their hypothesis was that the T cells might be shut down by the suppressive environment that tumors tend to build around themselves. They decided to investigate whether a vaccine could help the immune system get through those defenses.

The vaccine they created is designed to rally the CAR-T cells in the lymph nodes to fight the tumor. To do so, the vaccine contains a fatty molecule called a lipid tail that lets the drug travel straight to the lymph nodes, and once there, the active ingredient is an antigen that sends the T cells after the cancer.

"Our hypothesis was that if you boosted those T cells through their CAR receptor in the lymph node, they would receive the right set of priming cues to make them more functional so they'd be resistant to shutdown and would still function when they got into the tumor," says Darrell Irvine, senior author of the study.

An MIT team has developed a vaccine to stimulate T cells (red) to attack solid tumors in mice
An MIT team has developed a vaccine to stimulate T cells (red) to attack solid tumors in mice

The team tested the vaccine on mice that had glioblastoma, melanoma or breast cancer, and saw a huge improvement in the T cell response. The mice were given about 50,000 CAR-T cells and then given a booster vaccine the next day, and then again a week later. In 60 percent of the mice, the tumors were completely eliminated. That's likely thanks to the boost in CAR-T cell numbers, which two weeks after treatment make up 65 percent of the total T cell population.

By contrast, in the mice that were given CAR-T cells but not the vaccine, there was no effect on the solid tumors and the CAR-T cells themselves were hard to detect in the bloodstream.

The technique also seemed to prevent the tumors from coming back later on. The team injected new tumor cells, of the same type as the original tumors, into the mice 75 days after the treatment. Sure enough, the immune system had no trouble wiping them out again. Another 50 days later and the team injected different tumor cells, and again, the animals' CAR-T cells eliminated them.

As promising as the research sounds so far, it's worth keeping in mind that it was performed in mice, and might not translate to humans. That said, the team did preliminary tests with human T cells in the lab, and found that it works, which is a good first step towards human in vivo tests.

The team is hopeful that the technique could see human clinical trials in the next year or two.

The research was published in the journal Science.

Source: MIT

2 comments
2 comments
Mzungu_Mkubwa
This sounds (on the surface) like a huge breakthrough! Fasttrack it already and save some lives! (...but quietly, so Big Pharma doesn't find out and kill the cure to safeguard their revenue stream.)
Troublesh00ter
Yet another brilliant development. Now, can we deliver it at a price that won't ruin the patient?